Rapeseed
www.RapeseedBiodiesel.com

Our New Biodiesel Refineries Will Produce B100 Biodiesel 
for as Little as $.25 cents/gallon! (plus cost of feedstock)

B100 Biodiesel:  100% Clean, 100% Renewable, 100% Affordable 

B100 Biodiesel produced from a variety of feedstocks, grown on American and Canadian farms, will help to end our/your country's reliance on unstable, non-renewable, and "dirty" middle-east oil that pollutes our environment and causes inflated energy prices. 

Our company builds new Biodiesel Refineries throughout the U.S. and now, developing countries with a variety of feedstocks that include; canola, coconut, jatropha, jojoba, mustard seed, palm oil, peanuts, rapeseed, and soybean, among others.

In association with a major U.S. university, we incorporate the latest technologies in the production of B100 Biodiesel from oilseed crops, that will provide our biodiesel refineries with the highest efficiencies. We also are an importer of (vegetable) energy oils, where we refine it into Biodiesel fuel for use in our cogeneration and trigeneration power plants.  Additionally, we buy/sell/broker (vegetable) energy oils in the international market

For more information, call 832-758-0027

Renewable Energy Technologies provides the following power and energy project development services: 

• Project Engineering Feasibility & Economic Analysis Studies  

• Engineering, Procurement and Construction

• Environmental Engineering & Permitting 

• Project Funding & Financing Options; including Equity Investment, Debt Financing, Lease and Municipal Lease

• Shared/Guaranteed Savings Program with No Capital Investment from Qualified Clients 

• Project Commissioning 

• 3rd Party Ownership and Project Development

• Long-term Service Agreements

• Operations & Maintenance 

• Green Tag (Renewable Energy Credit, Carbon Dioxide Credits, Emission Reduction Credits) Brokerage Services; Application and Permitting

We are specialists in Renewable Energy Technologies, Demand Side Management and in developing clean power/energy projects that will generate a Renewable Energy Credit,  Carbon Dioxide Credits and/or Emission Reduction Credits.  Through our strategic partners, we offer "turnkey" power/energy project development products and services that may include; Absorption Chillers, Adsorption Chillers, Automated Demand Response, Biodiesel Refineries, Biofuel Refineries, Biomass Gasification, BioMethane, Canola Biodiesel, Coconut Biodiesel, Cogeneration, Concentrating Solar Power, Demand Response Programs, Demand Side Management, Energy Conservation Measures, Energy Master Planning, Engine Driven Chillers, Solar CHP, Solar Cogeneration, Rapeseed Biodiesel, Solar Electric Heat Pumps, Solar Electric Power Systems, Solar Heating and Cooling, Solar Trigeneration, Soy Biodiesel, and Trigeneration.

For more information: call us at: 832-758-0027

Look at the past 6 years production of B100 Biodiesel in the U.S.:

1999:  500,000 gallons of B100 Biodiesel were produced in the U.S. 
2004:  25 million gallons of B100 Biodiesel produced in the U.S.

THAT'S A 5,000% INCREASE IN ONLY 5 YEARS!

2005:  75 million gallons of B100 Biodiesel produced in the U.S.  

We are planning new Biodiesel plants throughout the United States, the Caribbean, Central America and Southeast Asia. We develop, build, and own B100 Biodiesel plants that use a variety of feedstocks, including;

*  Canola Biodiesel from coconuts - Investments for new Biodiesel
plants now planned for locations in the U.S. (Hawaii), Caribbean, Asia,
Central America and Southeast Asia (See our website at: 
www.CanolaBiodiesel.com for more information)

*  Coconut Biodiesel from coconuts - Investments for new Biodiesel
plants now planned for locations in the U.S. (Hawaii), Caribbean, Asia,
Central America and Southeast Asia (See our website at: 
www.CoconutBiodiesel.com for more information)

*  Jatropha Biodiesel from the Jatropha Curcas plant - Investments for
new Biodiesel plants now planned for locations in Asia, India, and
Southeast Asia  (See our website at:  www.JatrophaBiodiesel.com for
more information)

*  Palm Oil Biodiesel from Palm Trees - Investments for new Biodiesel
plants now planned for locations in the U.S., Caribbean, Asia, Central
America and Southeast Asia  (See our website at:
www.PalmOilBiodiesel.com for more information)

*  Rapeseed Biodiesel from coconuts - Investments for new Biodiesel
plants now planned for locations in the U.S. (Hawaii), Caribbean, Asia,
Central America and Southeast Asia (See our website at: 
www.RapeseedBiodiesel.com for more information)

*  Soy Biodiesel from Soybean Oil - Investments for new Biodiesel 
plants now planned for locations in the U.S., Asia, Central America and
Southeast Asia (See our website at:  www.SoyBiodiesel.net for more information)

Our New B100 Biodiesel Plants.

1. Large market potential for profits in new B100 Biodiesel production.
2. Our B100 Biodiesel plants are "optimum" designs.
3. We have markets for all of our B100 Biodiesel production, as well as the co-product(s).
4. We provide the "turnkey" project development.  
5. Help us make the world a "cooler, cleaner, greener" place to live!
6. We are also making investments in land that is located near major feedstock/plantations and locations of the following B100 Biodiesel feedstocks:
   
   * Coconuts
   * Jatropha
   * Palm Tree
   * Soybean

Grow Your Own "Green" BioDiesel
Increase Profits for Farmers, Improve the Local and Global Economy and Ecology, 
Decrease Pollution and End the Monopoly of OPEC/Foreign Supplies of "Dirty" Fuels!  

At an average production rate of 260 - 300 gallons per acre, Coconut Oil ("BioDiesel") is one of the most efficient energy crops, and second only to Crude Palm Oil that is produced from palm trees, and at an average yield of 600-700 gallons per acre.

Coconut Biodiesel

Introduction

Coconuts have been widely harvested in tropical coastal areas. The principal product of coconuts is copra, the dried flesh of the nut, from which coconut oil is extracted for use in food products such as margarine as well as in cosmetics and soap. In recent years the demand for copra has been falling, leading to declining incomes in areas that are heavily dependent on coconut and copra production. 

 

The coconut's copra or flesh can be dried and pressed to produce oil. Source: ITDG/Zul

 

South Pacific Island Economies Most South Pacific Islands are relatively poor, with average per capita incomes of less than $2,000 per year. As many as 80 per cent of these island citizens live in rural areas. There are hundreds of islands in the South Pacific ocean that include many popular destinations such as Tahiti and Fiji. Nearly all South Pacific islands are net importers of goods.

 

Copra is often produced by sun-drying the coconut flesh, though a higher-value product can be obtained by using a hot air drier Source: ITDG/Neil Cooper

Diesel fuel accounts for about US$9 million, or about 10 per cent of the total value of imports. If a sizeable proportion of imported diesel could be substituted by an indigenously produced fuel, it would make a significant difference to the balance of payments deficit.

Copra is the main export commodity of many South Pacific islands whose economies are heavily dependent on the price of coconuts and copra.  Lack of opportunity and underemployment are serious problems in the country, and realizing the full potential of coconut-based products could offer many opportunities for developing rural-based livelihoods and providing increased and more secure incomes.

 

The Coconut - A Truly Versatile Commodity Coconut is a very useful resource, not only for producing oil. The coconut fibre from the nut, known as coir, can be processed into mats, rope, fabrics, brushes and a biodegradable packaging material as an alternative to expanded polystyrene, as well as an environmentally friendly alternative to peat for potting and bedding plants. The coconut shell is good for making charcoal for fuel, and activated charcoal for purifying water and other liquids and gases. The residue from the pressing of the oil makes a good animal feed. "Straight" coconut oil can be used for cooking, as well as a fuel for lamps.

There is a growing interest in the health benefits of virgin coconut oil that has not been hydrogenated, a process which extends the shelf-life of oil products but has associated health risks.

Commercial Coconut Oil Production

Vegetable oil from soya and rapeseed (canola) has similar uses to coconut oil. In many countries the growing of soya has expanded and harvests of the crop have generally been good, so the market and price for copra have declined. On some estates on the islands of Efate and the Tafea group the coconut crop is no longer harvested, as this is not economic. Even where copra is produced, demand is mainly for high quality grades. It is very difficult to sell the poorer quality copra and make a profit. This mostly comes from smaller producers who use sun or smoke to dry the coconut. Drying coconut flesh slowly in the open air also risks bacterial infection.

Vanuatu exports coconut oil as well as raw copra. A single large mill, C.O.P.V. Santo, produces this. Producing Coconut Biodiesel for use as a biofuel on the island is possible but only after a biodiesel plant is constructed. This would help to improve rural incomes and economies and could mitigate the migration from rural areas to towns where there are few employment opportunities.

Environmental advantages for using biofuels such as Coconut Biodiesel compared with petroleum diesel include:

• Raw material resources are renewable and not finite;

• Trees grown for producing the fuel also re-absorb some of carbon dioxide released in burning the fuel;

• The fuel is cleaner-burning, releasing fewer particulates and noxious gases than diesel.

Coconut Biodiesel as Vehicle Fuel

The use of oil obtained from the nuts of the coconut palm (Cocos nucifera) for use as a B100 Biodiesel fuel has been supported the past several years by our company. The use of coconut oil and other vegetable oils in the production of B100 Biodiesel, or "Coconut Biodiesel," is not new.  Even straight vegetable oils such as coconut oil have been used used in the Philippines during the Second World War when diesel was in short supply. Since then the wide availability of diesel throughout the world and difficulties in running engines on coconut oil in cooler weather had virtually ended its use in this way. In recent years there has been a revival of interest in a number of countries, e.g. Thailand, India, the Philippines and some Pacific island states. This was due to the growing demand for diesel because numbers of vehicles and equipment were increasing, leading to higher prices and in some countries shortages. There were also concerns about growing import deficits and environmental pollution caused by increasing diesel use.

Technical difficulties

The main drawback with using coconut fuel oil in engines is that it starts to solidify at a temperature below 22°C, and by 14°C it is close to solid and does not flow at all. In tropical countries temperatures fall below 22°C on a significant number of nights throughout the year, and sometimes during the day in the cooler season. If the engine is started while the temperature is below 22 C, the fuel filter is likely to become blocked.

Transesterification

Transesterification is the process that converts vegetable oils into B100 Biodiesel.  Transesterification, the main product of which is a methyl or ethyl ester, has a low solidifying temperature. This process involves dehydration of the oil followed by reaction with sodium hydroxide (caustic soda) and methanol or ethanol. 

Coconut Oil Extraction

It has been suggested that better grades of copra should be used for producing coconut oil for B100 Biodiesel, however, this is untrue as the transesterification process resolves any issues that might have caused problems if using coconut oils as a fuel directly. 

Biofuel Industries possesses proprietary technologies relating to coconut oil extraction, which further reduces the costs related to Coconut Biodiesel production. Normally, high-pressure screw presses are needed to extract the oil from copra, and these need to be powered with electricity or hydraulics. Others have found that coconut oil can be extracted from copra at a significantly lower pressure than normal when it has been dried to a particular moisture content, and simpler manually operated presses can be used. It can be quite difficult to dry the copra to the right level, so it is better dry it out as far as possible in the sun or a hot air drier, then add the necessary amount of water. The water would be mixed in with the oil product and would need to be removed before it could be used for fuel.

This process is being disseminated under the designation of Direct Micro Expelling (DME) and small mills have been set up by local people on various island states, including Kiribati, Fiji, Tonga, Samoa and Tuvalu. Because the process can be carried out on a small scale this makes it accessible to coconut growers who can produce oil as a value-added product and are therefore less dependent on agents for the big oil producers who usually offer low prices for copra.

Coconut Biodiesel and the Future

Coconut Biodiesel for many regions is the future of energy and power production. Our related company, Cogeneration Technologies builds cogeneration power plants that are fueled with Coconut Biodiesel as the primary fuel to make power and energy.  Coconut Biodiesel has numerous economic and environmental benefits and helps developing countries become energy independent, and simultaneously eliminates the need for petroleum products that pollute the environment and damage the economies of developing countries. 

What is Biodiesel?

Biodiesel is an environmentally- friendly, renewable energy source that could also produce cost savings for taxpayers and private businesses and is produced from farmers that grow various fuel crops.  

Biodiesel produced from canola and rapeseed oil is superior to soy biodiesel. Especially due to the widely varying price fluctuations of soybeans. And because the feedstock (the oil produced from the fuel crop, such as soybeans, rapeseed or canola) to make biodiesel makes up about 80% of the cost for 
100 % biodiesel, basic economics dictate that the feedstock be obtained from the least-cost source, which is going to be either canola or rapeseed.  

Initial research conducted by the University of Saskatchewan and the AAFC Saskatoon Research Centre has found that each ton of renewable biodiesel fuel saves five times its weight in diesel fuel. As well, engines using biodiesel demonstrate wear rates as much as 50% lower than those using regular commercial fuels – effectively doubling engine life.

Canola is a member of the Brassica Family, which includes broccoli, cabbage, cauliflower, mustard, radish, and turnip. It is a variant of the crop rapeseed. Grown for its seed, the seed is crushed for the oil contained within. After the oil is extracted, the by-product is a protein-richmeal used by the intensive livestock industry. 

Canola is a very small seed, which means sowing depth must be controlled. The current sowing practice is to cover the seed lightly with soil, which provides more protection from drying out after germination. 

Canola is generally sown in autumn and develops over winter, with flowers emerging in the spring and is harvested early summer. With a growing period of around 180-200 days climatic effects such as sudden heat waves can reduce yields and hot dry conditions can limit its oil content. Summer weather ensures low moisture (less than 6%) at harvest. Carry-in stocks of canola are minimal because of a lack of on-farm storage. Canola is a good rotational crop, acting as a break crop for cereal root diseases. However for disease-related reasons, a rotation period of 3-5 years is required for canola crops. of iodine in grams absorbed per 100 ml of oil is then the IV. The higher the IV, the more unsaturated (the greater the number of double bonds available) is the oil and the higher the potential to ‘gum up’ when used as a fuel in an engine. Though some oils have a low IV and are suitable without any further processing other than extraction and filtering, the majority of vegetable and animal oils have an IV which does not permit their use as a neat fuel. 

Generally speaking, an IV of less than about 25 is required if the neat oil is to be used in unmodified diesel engines and this severely limited the types of oil that can be used.

The IV can be easily reduced by hydrogenation of the oil (reacting the oil with hydrogen), the hydrogen breaking the double bond and converting the fat or oil into a more saturated oil and reducing the tendency of the oil to polymerise. However this process also tends to increase the melting point of the oil and converts the oil into margarine. Only coconut oil has an IV low enough to be used without any special precautions in a unmodified diesel engine. However with a melting point of 25°C, the use of coconut oil in cooler areas would obviously lead to problems. 

Linseed oil could be mixed with petroleum diesel at a ratio of up to 1:8 to give an equivalent IV in the mid-twenties. Likewise coconut oil can be thinned with diesel or kerosene to render it less viscous in cooler climates. Obviously the solubility of the oil in petroleum also needs to be taken into account. Another method is to emulsify the oil or fat with ethanol. Most vegetable oils are a mixture of different esters such as oleic acid (main constituent of olive oil), ricinoleic acid (main constituent of castor oil), linoleic acid (main constituents of linseed oil), palmitic acid (main constituent of palm kernel oil) and so on. In an analogous way to that in which crude oil is refined to make a useable automotive fuel, canola oil needs to be transesterified to make an automotive fuel that is useable in unmodified diesel engines. 

When the oil is processed in a transesterfication process, the various fatty acids react with the alcohol to form a mixture of lighter esters and glycerol. The name of the specific fuel is called after the plant (or animal) source plus the alcohol. Made from rapeseed oil and methanol, the biodiesel is called Rape Methyl Ester (RME), from canola oil and ethanol, Canola Ethyl Ester (CEE), and from used McDonald’s cooking oil and ethanol or methanol, ("McDiesel").


What is Rapeseed Biodiesel?

Rapeseed, some varieties of which are used to make mustard and others to make canola oil, is the preferred biodiesel feedstock in Europe. Depending on the variety, rapeseed oil contains about 40 to 50 percent of its weight in rapeseed is oil, as compared with only 20 percent for soybeans. It can be planted and harvested with the same equipment used for small grains. In addition, rapeseed oil offers certain advantages in the production of biodiesel.


What is "Global Warming Potential?

Global Warming Potential (GWP) is the index used to translate the level of emissions of various gases into a common measure in order to compare the relative radiative forcing of different gases without directly calculating the changes in atmospheric concentrations. 

GWPs are calculated as the ratio of the radiative forcing that would result from the emissions of one kilogram of a greenhouse gas to that from emission of one kilogram of carbon dioxide over a period of time (usually 100 years). Gases involved in complex atmospheric chemical processes have not been assigned GWPs due to complications that arise.

Greenhouse gases are expressed in terms of Carbon Dioxide Equivalent. The International Panel on Climate Change (IPCC) has presented these GWPs 
and regularly updates them in new assessments. The instantaneous radiative forcing that results from the addition of 1 kilogram of a gas to the atmosphere, relative to that of 1 kilogram of carbon dioxide. 

What Are Greenhouse Gases?

Some greenhouse gases occur naturally in the atmosphere, while others result from human activities. Naturally occurring greenhouse gases include water vapor,
carbon dioxide, methane, nitrous oxide, and ozone. Certain human activities, however, add to the levels of most of these naturally occurring gases:

Carbon dioxide is released to the atmosphere when solid waste, fossil fuels (oil, natural gas, and coal), and wood and wood products are burned. 

Methane is emitted during the production and transport of coal, natural gas, and oil. Methane emissions also result from the decomposition of organic wastes in municipal solid waste landfills, and the raising of livestock. More information on methane.

Nitrous oxide is emitted during agricultural and industrial activities, as well as during combustion of solid waste and fossil fuels. 

Very powerful greenhouse gases that are not naturally occurring include hydrofluorocarbons (HFCs), perfluorocarbons (PFCs), and sulfur hexafluoride (SF6), which are generated in a variety of industrial processes.

Global Warming Potentials and Atmospheric Lifetimes (Years)

^a 100 year time horizon
^b The methane GWP includes the direct effects and those indirect effects due to the production of tropospheric ozone and stratospheric water vapor. The indirect effect due to the production of CO₂ is not included.

We provide turnkey services that removes Nitrogen Oxides, Nitrous Oxides and Sulfur Oxides. Unlike most companies, we are equipment supplier/vendor neutral. This means we help our clients select the best equipment for their specific application. This approach provides our customers with superior performance, decreased operating expenses and increased return on investment. Selective Catalytic Reduction systems are frequently used in removing NOx.

What are Nitrogen Oxides?

Nitrogen oxides, or NOx, is the generic term for a group of highly reactive gases, all of which contain nitrogen and oxygen in varying amounts. Many of the nitrogen oxides are colorless and odorless. However, one common pollutant, nitrogen dioxide (NO₂) along with particles in the air can often be seen as a reddish-brown layer over many urban areas.

Nitrogen oxides form when fuel is burned at high temperatures, as in a combustion process. The primary sources of NOx are motor vehicles, electric utilities, and other industrial, commercial, and residential sources that burn fuels.

Reasons for Concern

How can Nitrogen Oxides be Removed from the Environment?

Selective Catalytic Reduction (SCR) is a proven and effective method to reduce nitrogen oxides which is an air pollutant associated with the power generation process. Nitrogen oxides are a contributor to ground level ozone. 

How does Selective Catalytic Reduction work?

SCR Systems work similar to a catalytic converter used to reduce automobile emissions. Prior to exhaust gases going up the smokestack, they will pass through the SCR System where anhydrous ammonia reacts with nitrogen oxide and converts it to nitrogen and water.

* Some of the above information from the Department of Energy website with permission.

Biofuel Industries
Cogeneration Technologies
Renewable Energy Technologies
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